|Publication number||US7155704 B2|
|Application number||US 09/953,804|
|Publication date||Dec 26, 2006|
|Filing date||Sep 17, 2001|
|Priority date||Jun 30, 1998|
|Also published as||EP0969372A2, EP0969372A3, EP0969373A2, EP0969373A3, EP0969374A2, US6247143, US6256753, US6327668, US20020010880|
|Publication number||09953804, 953804, US 7155704 B2, US 7155704B2, US-B2-7155704, US7155704 B2, US7155704B2|
|Inventors||Emrys J. Williams|
|Original Assignee||Sun Microsystems, Inc.|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (44), Non-Patent Citations (4), Referenced by (17), Classifications (45), Legal Events (2)|
|External Links: USPTO, USPTO Assignment, Espacenet|
This application is a continuation of U.S. patent application Ser. No. 09/106,883 (now U.S. Pat. No. 6,327,668, issued Dec. 4, 2001) filed on Jun. 30, 1998, of which this application is a continuation filed under 37 CFR 1.53(b).
This invention relates to providing determinism in a multiprocessor computer system, to a monitor and processor for such a system and to a method of operating such systems. A particular application of the invention is to fault tolerant processing systems.
Many processing systems operate to a strict timing regime, changing their internal state on a known clock. Such a synchronous design of a processing system results in a large finite state machine. The internal state and outputs of this machine are entirely predictable, if inputs are presented in a known relationship to the clock. This determinism enables the construction of a fault tolerant multi-computer system by providing checking hardware, which compares the operation of one processor or set of processors against that of another identical processor or set of processors. The checking hardware can be arranged to check for faults in the operation of one or more of the processing sets by comparing the outputs of those processing sets on each clock.
Other processing systems do not behave in such a simple manner. Examples of this type are processing systems where the clock is not known, where multiple unrelated clocks are used, or where processor operation uses no clocks at all. These processing systems cannot be modelled as synchronous finite state machines. It may not be possible to present inputs to these processing systems in any known relationship to the computer's internal state. The detailed operation of these machines is non-deterministic. This prevents ordinary construction of checking hardware to compare operation between identical systems.
An aim of the present invention is to enable the provision of a deterministic multiprocessor system where at least one processor, or set of processors, operates asynchronously of another processor or set of processors.
Particular and preferred aspects of the invention are set out in the accompanying independent and dependent claims. Combinations of features from the dependent claims may be combined with features of the independent claims as appropriate and not merely as explicitly set out in the claims.
In accordance with one aspect of the invention, there is provided a monitor for a multiprocessor system. The monitor includes a plurality of processing sets, where at least one processing set is operable asynchronously of another processing set. The monitor is connectable to receive I/O operations output from the processing sets. The monitor is operable to synchronise operation of the processing sets by signalling the processing sets on receipt of progress indications indicative of a plurality of the processing sets being at an equivalent stage of processing.
In an embodiment of the invention, therefore, in addition to providing for the monitoring of I/O operations, a monitor is provided for responding to outputs for the processing sets indicative of the processing sets being at an equivalent stage of processing to synchronise the operation of the processing sets. In this manner, a plurality of asynchronous processors can be kept in step in a deterministic manner, at least at selected points during processing. This facilitates the cross checking of I/O operations for fault tolerant operation and also facilitates the timely delivery of interrupts.
The monitor can be operable, when an equivalent progress indication has been received from each of at least a plurality of processing sets, to return an acknowledgement signal to the processing sets from which a progress indication has been received. In certain cases, the acknowledgement signal may only be returned to the processing sets when a progress indication has been received from all processing sets.
The monitor is preferably operable to pass an interrupt from an I/O device to the processing sets with an acknowledgement signal for an equivalent progress indication. In this manner, the interrupts can be passed to the processing sets in a deterministic manner at an equivalent stage of processing.
The monitor can determine faulty operation of the processing sets on detecting non-equivalent operation thereof.
The monitor may be operable with only two processing sets, or with three or more processing sets. Where the monitor is used with three or more processing sets, a faulty processing set can be determined by majority voting. Where the monitor is used with only two processing sets, or where further processing sets have failed leaving only two processing sets, a faulty processing set may be determined by initiating processing set diagnostics on the processing sets.
In a preferred embodiment of the invention, the monitor is connectable to receive I/O operations output from the processing sets, and is operable to buffer the I/O operations, to compare an I/O operation output from a processing set to I/O operations buffered for another processing set for determining equivalent functioning of the processing sets, and to issue a state modifying I/O operation only on determining equivalent operating (or equivalent operation or functioning) of the processing sets.
In accordance with another aspect of the invention, there is provided a multiprocessor computer system. The system includes a plurality of processing sets, wherein at least one processing set is operable asynchronously of another processing set. The system also includes a monitor as described above.
In a preferred embodiment of the invention, the synchronising and fault monitoring operations are performed by a common I/O monitor unit.
Each of the processing sets can be configured, for example by the provision of appropriate control code and/or appropriate hardware, to record its progress in processing instructions and to issue a progress indication to the monitor as an I/O operation each time a predetermined progress increment has been recorded. Issuing the progress indication as an I/O operation, facilitates the use of a monitor unit for both synchronisation and fault monitoring purposes. However, the progress indication could instead be output as, for example, a signal on a dedicated or shared signal line.
Each processing set can include an instruction counter, with a progress indication for each progress increment of n counts. In a preferred embodiment the counter is implemented as a decrementer with a progress indication being issued when the decrementer underflows.
In order that the period between progress indications is relatively constant, it is advantageous to associate each instruction with a count value, whereby the counter is modified by the count value for an instruction on retiring of the instruction. The count value can be dependent on one or more of an instruction type, an operand and an address.
The recording of the progress of instruction processing can be suspended in a processing set for execution of certain instructions, such as an instruction executed by a software emulation in a processing set.
In order to allow for differences in processing speed in respective processing sets, while still maintaining processing sets substantially in step, a processing set is stalled on recording a progress increment when an acknowledgement signal for a previous progress increment has not been received by the processing set. The stalled processing set is kept stalled until the acknowledgement signal for the previous progress increment has been received by the processing set.
The monitor can be connected to receive and buffer I/O operations output from the processing sets, to compare an I/O operation output from one processing set to I/O operations buffered for another processing set for determining equivalent functioning of the processing sets, and to issue a state modifying I/O operation only on determining equivalent operating of the processing sets. A non-repeatable state modifying operation could be a read instruction with side effects or a write instruction. An embodiment of the invention can thereby respond to I/O instructions in an efficient manner, directly forwarding I/O operations which are not state modifying (i.e., where these may be withdrawn if required without corruption if a fault were subsequently determined), and buffering I/O operations prior to being forwarded until equivalent operation has been determined if the I/O operations are state modifying. For example, a read instruction having no side effects could be issued directly from the monitor on first receipt thereof from a processing set.
In a triple-modular-redundancy system (TMR), or higher order redundancy system, equivalent operating of the processing sets can be determined by majority voting on I/O operations. As an alternative, equivalent operating of the processing sets could be determined when all processing sets have output the same I/O operation. The policy for determining equivalent operating of the processing sets could be varied according to the number of processing sets being monitored.
To facilitate the determination of equivalent operations to be compared, the monitor can be operable:
to determine a buffer for each I/O operation dependent upon first invariant information (e.g., an I/O operation type and/or a processor number within a processing set) in the I/O operation;
to determine an order of I/O operations within the identified buffer dependent on second invariant information (e.g., an address phase ordering or an order number) in the I/O operations; and
to determine equivalent operation of the processing sets on the basis of equivalent third invariant information (e.g., write value data, an I/O command and an address) in the I/O operations at equivalent positions in equivalent buffers for the processing sets.
Each processing set may be a symmetric multiprocessor comprising a plurality of processors.
Where each processing set includes at least one resource for each processing set shared by the processors of the processing set the monitor can be configured to ensure equivalent ordering of mutexes (mutual exclusion primitives) for the processing sets for controlling access by the processors of the respective processing sets to the respective resources, thus maintaining equivalent operation of the processing sets.
The mutex ordering mechanism can form part of a monitor connected to receive I/O operations output from the processing sets for synchronising the operation of the processing sets by signalling the processing sets on receipt of output I/O operations indicative of a plurality of them being at equivalent stage of processing.
The monitor can comprise both a voter for determining equivalent ordering of I/O operations and common mutex storage accessed by voted I/O operations. It can also include a mutex manager. The mutex manager can include a mutex start register and a mutex stop register for each processing set. The mutex manager can include multiple sets of mutex start registers and a hash mechanism for accessing a mutex list for an I/O cycle.
In accordance with a further aspect of the invention, there is provided a processor for a multiprocessor computer system, the processor comprising a progress indication generator, the progress indication generator generating a progress indication representative of a determined increment of instruction processing greater than one instruction.
The invention also provides a method of indicating the progress of a processor in executing instructions in a multiprocessor computer system, where the processor is operable asynchronously of at least one other processor. The method may comprise the steps of: modifying a count value for each instruction executed; and outputting a progress indication for a determined number of counts.
In accordance with another aspect of the invention, there is provided a method of operating a multiprocessor computer system comprising a plurality of processing sets, wherein at least one processing set is operable asynchronously of another processing set and a monitor connected to receive I/O operations output from the plurality of processing. The method comprises:
detecting progress indications output by the processing sets; and
synchronising operation of the processing sets by signalling the processing sets on receipt of progress indications indicative of a plurality of the processing sets being at equivalent stage of processing.
Exemplary embodiments of the present invention will be described hereinafter, by way of example only, with reference to the accompanying drawings in which like reference signs relate to like elements and in which:
The I/O monitor unit (monitor) 18 is arranged to detect a difference in operation between the individual processor units 12, 14, 16 to determine faulty operation of one or more of those processing sets 12, 14, 16.
If more than two processing sets are provided, the monitor unit can detect a difference in operation between the processing sets and can employ majority voting to identify a faulty processing set, which can be ignored. If just two processing sets are used, or if following elimination of one or more faulty processing sets only two valid processing sets remain operable, a difference between the operation of the processing sets can signal faulty operation of one of the processing sets, although identification of which one of the processing sets is faulty can be a more complex task than simply employing majority voting.
The structure shown in
The structure shown in
In simple terms, in the case of an asynchronous system, the monitor unit 18 observes the I/O outputs from the processing sets 12, 14, 16 and also presents I/O inputs to the processing sets 12, 14, 16. The monitor unit 18 acts to synchronize the operation of the processing sets 12, 14, 16 as described in more detail below. If one processing set (e.g. 12) presents an I/O output and another processing set (e.g. 14) does not, the monitor unit 18 waits to see if the output of the other processing set 14 eventually arrives. It can be arranged to wait up to a time limit, the worst case difference in the operating time between the compared processing sets. If no output has arrived, or a different output has arrived, the monitor unit 18 can be arranged to flag the event as a mis-compare. This approach can be used to build a fault tolerant computer by having all I/O operations from the processing sets 12, 14, 16 pass through the monitor unit 18. The monitor unit 18 can delay passing on an I/O operation until it is sure that at least a certain number or proportion of the processing sets, typically a majority of the processing sets, concur. If the monitor unit knows that the I/O operation will not change the state of the I/O system—a read without side effects, for example—it can pass the I/O operation as soon as the first I/O operation output from the fastest compared processing set arrives, to enhance operating speed. Even if, in a fault tolerant processing environment, the system eventually decides that the cycle was a mistake, it will have done no harm, and the optimization could speed things up.
This ‘degree of synchronization’ is based on selectively stalling the processor(s) 30 of the processing sets 12, 14, etc. without the need for a synchronous clock. This is achieved by arranging for each processor to provide a progress indication so that the monitor can tell how far processing has proceeded. In the distant past, processors were arranged to output a pulse on the completion of each instruction. However, this is no longer appropriate. Nowadays, instructions are completed faster than can be signaled externally. Also, the out-of-order nature of execution makes it difficult to decide exactly when an instruction has completed. Is it when the instruction itself is finished, or when the instruction and all earlier instructions are finished? These complications need a more sophisticated progress indication.
The progress indication is used by the monitor to slow down a processor so that it does not become too far out of step with another. For this, processors also need to provide some way to allow the monitor to stall them.
Progress indications should be generated such that the time intervals between them are approximately constant, such that they do not come so fast that as to make electrical signaling impractical, and such that progress indication is deterministically related to the instructions executed. For stall requests, it is desirable that the external electronics does not have to be exceptionally fast either to request or to refrain from requesting a stall. When the external electronics does not request a stall, the processor should not be slowed in any way. However, when the stall is requested, the processor should halt in a precise state, with all instructions up to the stalled instruction retired, and no instructions beyond it issued.
One example of a mechanism for providing a suitable progress indication is to assert an output every N instructions, where N is some fixed (or even programmable) number of instructions. This can be achieved by providing an instruction counter which outputs a progress indication every N instructions. This works well when all the instructions take approximately the same time to execute. If the instructions vary in execution time, or some instructions may be extended by external communications (like an I/O read operation), this simple mechanism may provide time intervals between progress indications that are too variable for convenience.
A more sophisticated mechanism for providing a progress indication enables the instruction count to vary according to the real state. This could take into account the variation in instruction timing to provide more-or-less constant intervals between progress indications.
Where reference is made to the ‘real state’ this is to be understood to encompass the programmer visible state, subject to certain constraints. Thus it includes the content of a fixed set of registers, including the program counter and main memory, but excludes transitory elements such as caches and intermediate pipeline values. The ‘real state’ includes all data required for context switching between processes plus, for example, operating system status data.
To provide determinism, the converter 61 does not take into account data not included in the real state of the processor, such as the congestion in pipelines or whether a variable is in a cache or not. The approximate time equivalent, a number, is fed to the decrementer 64, where it forms a decrement value to be subtracted from the current value stored in the decrementer 64. When the decrementer 64 underflows through zero, it produces a carry output 65 which is received by a progress controller 66. The progress controller 66 can then output a signal externally as the progress indicator 67. Before the next decrement operation, the decrementer is reinitialized to an initial value from a register 63, which may be programmable.
The instruction-to-count converter 61 may include stored state information. One application of this is accounting for software emulation of particular instructions. When the converter 61 detects (e.g., from the instruction type information) that an instruction is to be emulated instead of executed, it sets an internal flag to show that it should no longer count instructions, equivalent to producing decrement values of zero. When the converter 61 sees the return-from-emulation instruction at the end of the emulation routine, it produces the decrement value for the emulated instruction, which it could compute internally or which could be provided by special code in the emulation routine. In this way, a processor which emulates some instructions could be made equivalent to one which executes them all in hardware, for comparison purposes.
The carry output 65 can be used by the progress controller 66 to provide a progress indication 67 output from the processor as a pulse or a step on a signal wire. Alternatively, the carry output can lead to the progress controller 66 issuing a special progress indication I/O cycle to be scheduled on the processor I/O bus. For example, the processor can issue a special read cycle on the I/O bus at each progress indication. This is illustrated schematically in
Before moving to
Along with the responses 2003 and 3003, the monitor can send interrupt information. This could be as simple as a one-bit interrupt request or could be a whole packet of interrupt data. The processor can use this to determine whether it is going to take an interrupt or continue normal processing. If the processor is designed to take interrupts only at the precise instruction associated with an internal progress indication, then any requested interrupt will be taken by processor 2000 at progress indication 2004, and by processor 3000 at 3004. For lockstep processors, this would be at the precise same instruction on processors 2000 and 3000. The monitor acts to keep the progress indications in step, and can be sure that both processors take the interrupt on the same progress indication without ambiguity. The processors themselves ensure deterministic delivery of progress indication, affected only by their real state.
Interrupts delivered in this way can be delayed by about two progress indications before the processor begins to execute the interrupt routine. It is desirable to arrange that this delay does not produce an unacceptable performance.
When processor 2000 is nearing progress indicator 2004, it may well want to begin issuing instructions beyond that precise instruction implied by 2004. Instructions execute out-of-order for speed. In order to provide a precise interrupt model at this precise instruction, this may not be allowed. This would slow the processor. In order to avoid this, the processor could be designed to ignore this restriction when response 2003 has already been received and the processor already knows that no interrupt will be taken at 2004. So, if 2003 occurs early enough before 2004, the processor will continue at top speed. This provides a mechanism for delivering interrupts precisely at deterministic instructions independent of the operating speed of the processor and without slowing the processor unnecessarily, which is precisely what is needed in an asynchronous lockstep system.
Instead of performing a special progress indication I/O cycle on the I/O bus, different signaling means can be used for fundamentally the same protocol. Wires separate from the I/O bus can carry the processor special cycle request to the monitor and carry the response back. This allows the progress indication interval to be short without consuming I/O bus bandwidth. If wanted, the processor can perform a special I/O cycle after delivery of an interrupt request to fetch a packet of interrupt data.
In fault tolerant systems, the monitor is arranged to deal with the possible problem of a missing progress indication. An upper bound is set for the time between progress indications. The upper bound chosen in any particular implementation can be based on processor speed variations and could be defined as a multiple of the normal speed of the processors. The upper bound is typically defined as a function of the normal time between progress indications. Accordingly, if the progress indications are 1 us apart, the upper bound might be 2 us. If the progress indications are 100 ms apart, the upper bound might be 200 ms. This would mean that a monitor would have to wait at least 200 ms instead of 2 us before beginning recovery action if no progress indication arrived. This illustrates that it is desirable to have short and well-defined intervals between progress indications.
Accordingly, when an instruction is dispatched, the decrementer 64 can be updated at step 74, following determination of an instruction count value by the converter 61 at step 72. Although a decrementer 64 is shown in
If, in step 76, the decrementer 64 has not underflowed, then control passes back to step 72 for the next instruction. However, if the decrementer has underflowed, a test is made in step 78 to determine whether an acknowledgment for a previous progress indication has been received. If an acknowledgment for a previous progress indication has been received, a progress indication is sent to the monitor unit at step 86, and a sent/acknowledgment indicator 68 (see
If, in step 78, it is determined that the set/acknowledgment indicator 68 is still set, indicating that a progress indication has been sent, but no acknowledgment thereto has been received, the processor is stalled in step 80. The processor remains stalled until it is determined in step 82 that the sent/acknowledgment indicator 68 has been re-set, indicative of receipt of the acknowledgment for the progress indication previously sent. At this time, the processor is released in step 84. Control then passes to step 86 where the next progress indication is sent and the sent/acknowledgment indicator 68 is once more set. Control then passes back to step 72 for the next instruction.
Accordingly, it can be seen that, according to
As mentioned above, the I/O progress indications can be sent to the monitor unit 18 as specific I/O operations. Alternatively, they could be supplied over a special hardwired connection (not shown).
As shown in
It will be seen that the combination of the logic in the processing sets 12, 14, etc. described with reference to
While the processing sets 12, 14, etc. may not be strictly deterministic, they should respect some constraints on their operation. It should be possible to perceive an order in the instructions the processors execute. Normally, this is the order in which the instructions are written in the program, modified by branch operations. Processors may internally reorder the instructions, and may execute some instructions in parallel, but the eventual effect should be the same as if the instructions were executed in the order the programmer expects. If this is not the case, the program result may not be as the programmer expects. (In this regard, interrupts and DMA will be discussed below). In addition, the order of I/O operations presented as outputs to the monitor unit 18 are determined absolutely by the program, independent of the detailed timing of execution. This is typically the case, as it is difficult to manage I/O devices without this capability. It should be noted, however, that processors routinely reorder writes behind reads for speed. It is possible to provide for this and still carry out effective I/O operations. This can be managed with separate read and write comparison channels in the monitor unit, providing the processor is guaranteed not to reorder writes among themselves or reads among themselves, and will deliver at least the first read and the first write to the monitor unit at once.
The I/O bus interfaces 52 connected to the respective I/O buses 22, 24 of the processing sets 12, 14 are operable to identify write and read operations and respectively to buffer the write and read operations in respective buffers 114/115. These buffers 114/115 represent one example of a configuration of the buffers 54 of
In a triple modular redundant (TMR) arrangement with three processing sets, the determination of which of the processing sets is faulty can be accomplished by majority voting in the writes and reads voters 116 and 118, respectively. Alternatively, in an arrangement where there are only two processing sets (i.e. a dual modular redundant arrangement (DMR)), the determination of which of the processing sets is faulty can be more complex, but can still be determined by diagnostic techniques.
The writes and reads voters 116 and 118 can be arranged to pass write and read operations via the common I/O bus interface 58 to the common I/O bus or buses 20 in accordance with appropriate strategies. For example, as indicated above, if an I/O operation will not change the state of the I/O system (a read without side effects, for example) the monitor unit can be arranged to pass the I/O operation as soon as the first I/O operation output from a processing set arrives. In other circumstances, where an I/O operation will change the state of the I/O system (a write operation or a read operation with side effects, for example), the monitor unit can be arranged to pass that I/O operation only when a majority (which might be just one in the case where only one remaining processing set is operable), or possibly a plurality, of the processing sets have output the I/O operation. In other words, a state modifying I/O operation is issued to the I/O bus when the monitor unit determines equivalent operation of the processing sets.
It will be appreciated that an initially TMR system could become a DMR system where one of the processing sets is determined to be faulty. Accordingly, equivalent operation of the processing sets can be determined in accordance with a policy which varies according to the number of valid processing sets currently being monitored.
There should be no component of the processing sets which affects eventual operation in a non-deterministic way. For example, a timer in each processing set visible to program operation would not necessarily present the same value at the same step in each program, and is not allowed. On the other hand, the provision of a register which counts the number of instructions executed, as described above, is deterministic. If the ‘real state’ of a processing set is the total state of all the data which may affect program execution, taking into account caches and other temporary stores, then components are not allowed to affect the real state non-deterministically with respect to the effective order of instruction execution. If desired, a timer can be placed on an I/O bus.
Given that the I/O operations are ordered by the program, and the program is the same for all the processing sets, the monitor unit should see the same I/O operation presented by each processing set at the time any I/O operation is effected.
In order to keep the real state of the processing sets the same when they receive an interrupt, the interrupt is arranged to be taken by each processing set after the same instruction. If the processing sets are not doing an I/O operation, the monitor unit cannot guess at where the instruction counters of the processing sets point. The monitor unit 18 needs some way to deliver the interrupt in sync.
As described above, each processor in a processing set issues a special I/O operation in a predictable way (equivalent to every 100 instructions, for example), which allows the monitor unit 18 to observe how far the processing sets have progressed. By keeping the count of the special I/O operations, the monitor unit can deliver the same interrupt on the same instruction to the processors concerned.
If the special I/O cycle is a read which stalls the processor, the monitor unit can choose always to hold up the faster processor which does the I/O operation first, until the slower processor has caught up. This does not slow the system much, for, overall, it cannot proceed faster in the long term than the slowest processing set being compared. This way, the special I/O operations would proceed in step. When an interrupt needs to be sent, the monitor unit arranges for this to be returned with the response to the progress indications. This is done in a very convenient manner by arranging that the progress registers 94 of
The common I/O bus interface 58 could be responsive to a received interrupt from the bus 20 to convert the interrupt signal to interrupt data for storage in respective progress registers 94.
It should be noted that when a processor carries out this special read cycle, the processor can progress instructions around the read cycle which do not depend on the read data. In general, any instruction which does not depend on the read data can be retired from the execution unit. However, this does not lead to a precise exception model. If the read data is replaced with an exception, the real state of the processing sets during exception processing is not predictable. This is not appropriate for the special progress indication I/O cycles of a lockstep system. It is necessary, for this particular type of instruction and bus cycle, that exceptions be precise around the special I/O cycle. If an interrupt is delivered, the instruction on which it is delivered must be predictable, and all instructions up to that one should have completed, and all beyond it should not have issued.
In modern processing sets, bus cycles to I/O devices are not necessarily simple. Bus cycles can be broken down into separate address and data phases, with the data phases disconnected from and not necessarily in the same order as the address phases. Multiple I/O operations (I/O cycles) can be in progress at one time, and I/O instructions may be retired from the execution unit before the first evidence of the I/O operation has appeared from the processor, let alone been completed.
To facilitate the determination of equivalent operations to be compared, the monitor can be configured to be operable:
to determine a buffer for each I/O operation dependent upon first invariant information (e.g., an I/O operation type and/or a processor number within a processing set) in the I/O operation;
to determine an order of I/O operations within the identified buffer dependent on second invariant information (e.g., an address phase ordering or an order number) in the I/O operations; and
to determine equivalent operation of the processing sets on the basis of equivalent third invariant information (e.g., write value data, an I/O command and an address) in the I/O operations at equivalent positions in equivalent buffers for the processing sets.
As an extension of the arrangement shown in
It should be noted that this is different from accesses by the processor to main memory which access the ‘real state’, of the processing set. This architecture places no restrictions on main memory access, which need not be in the same order on different processing sets in order to achieve lockstep operation.
There are several circumstances in which an I/O cycle might need to trigger a data access exception in the processor. These are
For write cycles, none of these events need trigger an access exception in that:
For read cycles, for cases 1 and 2 above, it is not necessary to return an access exception in order to recover properly. As these are I/O cycles, they are generated by device drivers. Through the use of conventional device driver hardening, the driver software hardens the driver against faults in data read from the device. A check routine in the driver can typically detect a fault, even if there is no other clue than the presence of corrupted data.
The I/O interface 58 is subsequently operable to respond to an I/O operation from at least one of the processing sets for a resource (device) 130 or 132 already labelled as defective by means of the flag in the status register 134 to prevent the I/O operation from being passed to the external bus 20. In the case of reads it is further operable to return a predetermined data response to the initiating processing set. In the case of writes, it is operable to discard the operation and to terminate by returning an acknowledgement to the initiating processing set. As will be noted in
It is thus possible for the monitor unit to bar access to devices that have once returned faulty data, so that the driver soon notices the problem. If the monitor unit returns unspecified data for the problematic I/O cycle, and does not signal an access exception, the processing sets will continue in sync, no matter what the complexity of the I/O cycle and instruction ordering rules. The monitor unit has to return the same faulty data to the two processing sets. The monitor unit may choose to signal the fault with an interrupt later.
For a read cycle in case 3 above, it is important that the access exception routine prevent the processor from acting on faulty data. On return from the exception, the processing set can re-run the I/O read cycle and proceed without the underlying device driver knowing anything of the diagnostic event triggered by the out-of-sync condition. When the access exception routine is in progress, it does not matter whether the ‘real state’ of the compared processing sets is the same. The processing sets are already out of sync. More divergence is immaterial. Only one of the processing sets is going to be deemed to be correct when a re-configuration is done to recover from the fault. Therefore, it does not matter exactly what instructions have been completed when the access exception occurs. Provided that some trace in the processor allows the processor to recover and re-run the I/O operation where it left off, the exception need not be precise.
For triple-modular-redundant (TMR) fault tolerant systems, it is advantageous if two processing sets can carry on in sync after an out-of-sync (OOS) event, instead of just one. For this to happen, the data access exception on an out-of-sync I/O read cycle would have to be precise. A less restrictive approach is to have the monitor unit recognise the easy diagnostic signature of the two-to-one vote of a TMR system and automatically re-configure the system on an out-of-sync event. The monitor unit will, on the OOS event, immediately start ignoring the output of the mis-comparing processing set, and carry on in a dual-modular-redundant (DMR) configuration with the remaining two processing sets. The I/O cycle in progress can be completed without any exception, and still the data access exception need not be entirely precise.
If I/O cycles are split into separate address and data phases, and the order of the cycles is defined by the address phases, it is not necessary that the data phases be in the same order on the compared processing sets. It may be convenient for the monitor unit that this is the case, but changes in the detailed bus timing are part and parcel of asynchronous lockstep operation, and reordering of the data phases is just a detail of the bus timing. All that is needed is that there exists at all times a deadlock-free mechanism for the monitor unit and the processors to make progress. Resources and protocols must exist so that enough pending I/O cycles become visible at the monitor 18 to perceive matched operations. An I/O cycle from one processor in a processing set may not block an I/O cycle from another .
One optimisation which the processor may employ is to merge multiple I/O accesses into a single bus cycle when convenient. For example, if two one-byte reads are pending to adjacent I/O addresses, the processor might issue them as a single two-byte read. This is a general problem for I/O drivers. If one processing set issued two single-byte cycles, while another issued one two byte cycle, the monitor unit has a harder job. This sort of rearrangement can cause I/O device mis-operation, even in an ordinary processing set. Therefore, processing sets do have mechanisms which ensure that this merging need not happen on I/O cycles. All that is needed for asynchronous lockstep operation is to ensure that these optimisations are suppressed for all I/O cycles.
Thus we see that asynchronous lockstep operation actually places remarkably few restrictions on I/O implementation.
In a preferred embodiment of the invention, the monitor unit 18 allows sophisticated processor operation around I/O cycles with the return of data instead of an access exception for some faulty I/O cycles.
Processors may perform instruction fetches and data reads and writes through memory management units (MMUs). The intent of the MMU is to provide a virtual address space which can be translated into a real address space. The implication is that if the translation does not succeed, and the virtual datum is not mapped onto the physical space, an exception can be taken in the processor to re-configure the system without the underlying operation being disturbed.
Page miss exceptions are often somewhat de-coupled from the event which caused the page miss. For example, an instruction prefetch might cause the page miss handler to be triggered, rather than instruction execution. A write data page miss might be discovered long after the store instruction has been retired from the execution unit. On asynchronous systems, this lack of precision could cause compared processing sets to diverge. A solution to this is to have precise page miss exceptions for both data and instructions. The page miss exception handler should be entered precisely when the missing instruction is needed, or the missing data read or written. Instructions previous to this event should have completed, and instructions following this event should not have started.
The description of asynchronous lockstep operation so far divides processing sets into a core with a processor and a ‘real state’ of main memory, separated by the monitor unit from I/O devices. In the following, extensions will be described for processing sets having multiple processors.
For multi-processor (MP) operation, I/O operations are preferably labelled with their processor number. The monitor unit 18 is arranged to compare I/O operations processor-for-processor across compared processing sets. This can be achieved with multiple buffers in the monitor unit for I/O operations received from the processing sets, as described above. One processor P0 of a processing set 12 may produce the next I/O cycle first. Another processor P1 of the processing set 14 may produce a different I/O cycle first. This is not a fault. The monitor unit has hardware that sorts this out and waits for another processor to do an I/O cycle that matches up. If the system is working correctly, this will eventually happen. If the system is not working correctly, the monitor unit must trigger a re-configuration in some way. However, this routine extension is not the real problem with MP asynchronous lockstep operation.
In MP machines, the processors act independently on the ‘real state’. Processors in the separate compared processing sets do not progress at the same pace, and the relative progress of multiple processors in each independent processing set is not related. Imagine two compared processing sets, a and b. Each processing sets has an identical real state and two processors, P0 and P1. P0 and P1 both reside in the core with access to the real state without monitor unit interference. This is highly desirable for speed. If P0 and P1 in each processing set both need a new resource, say a page of memory, they will act to acquire the page from the pool of spare pages held in the real state. In a first processing set PUA, P0 is slightly faster and acquires the next page. In a second processing set PUB, P1 is slightly faster and acquires the next page. The real states of the processing sets have diverged, never to re-converge. In a single processor system, lockstep operation depends on the deterministic delivery of interrupts, which the monitor unit can arrange. In an MP system, lockstep operation also depends on the internal details of core operation, invisible to the monitor unit.
To overcome this, in an embodiment of the invention control is exercised over the way the multiple processors of a single processing set use mutual exclusion primitives (mutexes). In practice it is the various processing threads in the processors which use the mutexes. In an MP machine, to provide a reasonably simple programming environment, the processors (or rather the threads executing therein) use mutexes to manage access to areas of main memory. In fact, normally, the processors are not all working on the same part of the real state at all, but on orthogonal regions. The regions can have arbitrarily complex shapes—the addresses belonging to a region can be scattered everywhere—but regions do not overlap. When a processor (processor thread) needs access to an address in a region which may simultaneously be in use by another processor, it first acquires ownership of a mutex which the software provides specifically to prevent misunderstanding. Only one processor (processor thread) at a time gains write access to a region. While it has write access, no other processor (processor thread) has read access.
It is important to note that not all inter-processor interactions are strictly governed by mutexes in current programming. Other less dogmatic and even ad hoc mechanisms can be used. For example, one processor can be given implicit permission to write a location, with all processors permitted to read the location. Shared memory is available to user programs, and devious schemes can lie in applications unknown to the system. However, it is possible to transform all of these programs into programs that use mutexes.
Proper use of mutexes makes the processors of an MP system each act on its own portion of the total real state, with the important restriction that other processors will not modify that portion while the processor has access to it. So, if the partial real state visible to a processor is dependent only on that one processor's actions, then the processor's actions, which are dependent only on the visible part of the real state, will be determined by the initial value of the visible real state for that processor. Now that programming has ensured that the changes to the real state are determined by the initial value of the real state, the only variable left undetermined is the order of acquisition of the mutexes by the various processors. If the processors (processor threads) in the various processing sets acquire and release mutexes in the same order, then all the modifications to the real state are wholly determined. So the two restrictions for MP asynchronous lockstep operation are that the program properly uses mutexes to enforce individual processor access to parts of the real state that may be modified, and that the hardware arranges for the mutexes to be synchronized on the compared processing sets.
The monitor unit 18 can provide hardware intervention to enforce mutex ordering. Code for mutex acquisition and release can be changed to access the monitor unit. There are then many different methods for the monitor unit to control ordering.
One approach for monitor unit control of mutex ordering is to have a per-processor mutex start and end register in the monitor unit for each processing set as represented in
Another approach for the monitor unit to control mutex ordering is to provide multiple mutex start registers per processor. This small number of start registers can be mapped onto the large total number of mutexes by a hash translation mechanism in the mutex software executed by the processors. Which mutex the processor was contending for would determine which start register was accessed, but there need not be a one-to-one relationship. The monitor unit would then only hold up processors contending for mutexes on the same start register. This would reduce delays in the event that processors spent much time contending for mutexes. Note that only one stop register would be required per processor. Each processor only contends for one mutex at a time. If hash tables are used, the mutexes managed by independent entries in the hash table manage independent real state of the processor sets.
Another approach for the monitor unit to control mutex ordering is to have the monitor unit implement hardware mutexes. Read of a mutex register in the monitor unit can return a value to the processor, 0 or 1, depending on whether the acquisition was successful. A write to the same register by a processor could signal to the monitor unit that the mutex was released. However, care needs to be taken in this case because of the restrictions this places on the deterministic relationship between I/O reads and writes. Alternatively, a read of a different address could signal mutex release. Reads for mutex acquisition can delay returning data to ensure ordering. The monitor unit can provide multiple registers for each processor to implement many mutexes.
A processor P of a processing set (e.g., 12, 14) requests 121 ownership of a mutex N by issuing an I/O read request for the mutex request N register 126 address. The mutex processor 120 handles this request 121 and examines the mutex store 122 associated with mutex N. There need not be a one-to one relationship between mutex store hardware and the mutex registers. The mutex store 122 contains a value which indicates whether the mutex is currently owned or not owned. Either way, the mutex processor 120 ensures that, after this event, the mutex store 122 indicates that the mutex is owned. The mutex processor 120 returns to the processor a mutex response 123 which allows the requesting processor P to tell whether the original value of the mutex store was owned or not owned.
To relinquish ownership of the mutex N, the owning processor P reads the mutex release N register 128 address. The returned value is immaterial. The mutex processor changes the value in the mutex store for mutex N to indicate that it is not owned.
If a processor number is associated with the I/O cycles to the mutex hardware, the mutex processor 120 can detect the possible error of a request for one mutex from a processor P which already owns that mutex. Alternatively, this programming model can be defined to be correct, and the mutex processor 120 can store the ‘number of times’ a mutex is owned by one processor P in the mutex store, only releasing mutex ownership when this number has been decremented to zero by repeated mutex releases, or releasing it on the first mutex release, as the designer wishes. Similarly, the mutex processor 120 can detect the likely error of the release of a mutex which is not owned by the releasing processor P. Diagnostic information about these errors can be presented.
To use this mutex hardware in an asynchronous lockstep fault tolerant system, it can be placed on an I/O bus. The monitor unit 18 presents only voted and synchronized cycles on the I/O bus and so will automatically provide equivalent mutex ordering on multiple processing sets. No additional monitor capabilities are needed.
Yet another approach for the monitor unit to control mutex ordering is to use a combination of the above approaches. A relatively small number of high-use mutexes can be implemented in monitor unit hardware, as in the previous paragraph, and one or more start/stop registers per processor can provide control for an arbitrary number of less critical mutexes in main memory.
For simplicity of programming, the monitor unit can have all the processors for all the processing sets access the same address in the monitor unit mutex registers for the same mutex, and use hardware methods to distinguish between processing sets and processors for mutex ordering.
It should be noted that the mutex ordering scheme allows the monitor unit to return read success immediately the first processor on the first processing set reads a monitor unit mutex register. Other processing sets are guaranteed to catch up eventually, provided they are operating in sync. If they do not catch up, they are already out of sync, and extra divergence does no harm. However, as usual, such speed-enhancing optimisations are eventually limited by the need to wait for the slowest processing set in the end.
As mentioned above, a properly programmed MP system will limit processor access to a portion of the real state which will not be modified by another processor. If this is not the case, an asynchronous system cannot be made deterministic by mutex ordering. It may happen that software faults do not provide this constraint, and processors do access real state which is being modified. This can lead to a divergence in the real states of the compared processing sets, because of divergent ordering of accesses to the real state. These software faults are not uncommon in ordinary MP systems, and lead to difficult MP bugs. Programs assume they have write access to data when, in fact, they do not. An asynchronous lockstep method of configuring a system provides a way to find these faults relatively quickly.
In an ordinary MP machine, mutex programming faults lead to incorrect behaviour when the programs of two or more processors happen to conflict over accesses to data intended to be protected by the mutex. This may be a low probability vent. It can go undetected for long after the real state of the processing set is modified, and the evidence can be obscured by the time the fault comes to light.
In an asynchronous lockstep machine, the same programming fault may cause the real states of compared processing sets to diverge. The congruence of compared real states is relatively easily checked (see below) and divergence can be detected relatively quickly, within a few instructions. The problem of detecting mutex programming errors has been transformed from a complex one which requires detailed knowledge of the purpose of each mutex to a mechanistic one which only requires comparison of real states. Examination of the recent behaviour of the processors after a real state divergence, perhaps with a logic analyser, will soon lead to the root cause of the error.
This transformation does not increase the probability of tripping over the access conflict, which still depends markedly on how often the programs visit the problem area of real state. However, a change in the way the processors work in each compared processing set can increase the chance that the programing fault will lead to a detectable real state divergence. Specifically, to look for mutex faults, a system could be arranged to ensure that the order of operation of the processors in compared processing sets is different in each processing set. For example, the processor P1 in the processing set PUA could artificially be slowed to half rate. The most extreme example of this occurs when in the processing set PUA, the processor P0 is allowed to complete all its instructions, then the processor P1 runs, while in the processing set PUB, the processor P1 completes, then the processor P0 runs. This could be achieved using the regular interrupt I/O cycle mechanism described above. The monitor unit could be arranged to enforce this specific ordering as an experiment to detect software locking faults. The processor P0 on the processing set PUA could be arranged to run, say, 10000 instructions while the processor P1 is stalled, and vice versa on the processing set PUB. Of course, if processors stall waiting for I/O in this time, the monitor unit must allow the appropriate processor on the compared processing sets to proceed, to avoid deadlocks.
Interrupt delivery needs only to be deterministic to each processor individually. It is not necessary to reach a common global state for each compared processing set before delivering an interrupt. Each processor can generate interrupt synchronization cycles and receive interrupts separately, and the mutex ordering mechanism will take care of everything else.
There may be hidden interactions between processors in ordinary MP processing sets which require transforming into regular mutex schemes for MP a synchronous lockstep machines to work. Some examples of these follow.
Processor P1 writes flag F to 1 to indicate that data D is available. Processor P0 reads D into some private store, then writes F back to 0.
This is a perfectly valid two-processor communication system. It can be transformed into a mutex-controlled system by having access to F managed by mutex MF. Then the operation would be:
P1 acquires MF
P1 writes F to 1
P1 releases MF
P0 acquires MF
P0 reads F
P0 reads D
P0 writes F to 0
P0 releases MF
Some processors automatically maintain page tables in hardware. The page tables exist in the real state of the machine. The MMU TLB in the processor can usually be considered a cache of the page table in memory, and thus not of much effect on the real state. However, if the TLB automatically writes used and modified page information to main memory page tables, this could be written differently among multiple processors on compared processing sets. Software mutexes will not help here. Programs have access to the page tables which may be modified by the hardware of various processors. The hardware knows nothing of the mutex schemes. One fix for this is to avoid hardware update of page tables. Page table modification can be done by software in page miss exception routines. The miss routines and other code which accesses page tables can use mutexes, and the monitor unit's mutex-ordering scheme will fix the determinism problems. In order for this to work, the page miss exceptions must be precise.
Base operating system update of page tables in memory, especially flushing of no-longer-valid entries, must be coordinated between processors to ensure deterministic operation. A hardware table walk of a page table to load an entry must be co-ordinated with another processor's modification of that entry. This is easy if page miss handling is done by software exception, not hardware table walk. The mutex ordering system handles the problem.
I/O devices often use direct memory access (DMA) to read or write the real state of the system efficiently. The incorporation of DMA an asynchronous lockstep machine will now be described.
One way to handle DMA is for the processor to write a command register in the I/O device, for the DMA to complete, and for the I/O device to provide a completion status register or interrupt. This sequence acts in the same way as a mutex to control access to the area of main memory used for I/O communications. Processors normally avoid reading or writing this communication area while the I/O device is transferring it. This can be accomplished through ordinary programming. In an asynchronous lockstep machine, the monitor unit 18 needs to provide no extra ordering other than that required for the previously-described comparison of I/O cycles (or interrupt delivery, if interrupts are used for completion signalling). Conventional ordering requirements from ordinary processing sets take care of all other problems. The monitor unit can transform the single DMA access from the I/O device into a memory cycle for each of the compared processing sets. For a write cycle, all the processing sets are written. For a read cycle, read data from all the processing sets can be compared.
Another DMA technique is for the command buffers managing DMA to be in main memory. When this is the case, programs need extra care to ensure that asynchronous determinism is maintained. If no extra care is taken, when DMA completion status is written to main memory, processing set PUA could sample the completion status before it is updated, and processing set PUB could sample it after it is updated.
One way of providing protection against processor-DMA interaction when command and status buffers are in main memory is to provide per-processor per-processing set DMA sampling registers in the monitor unit, as represented in
In the above example, it is possible to provide multiple DMA start and stop registers, where each register controls DMA access for a separate I/O device. It is not necessary to inhibit DMA for all devices when a processor is accessing the DMA control block in main memory for only one device. The monitor unit is arranged to know from which device each DMA cycle comes.
There now follows an description of the provision of signatures and analysers.
Asynchronous processing sets can look completely different in detail while executing exactly the same change to their identical real states.
For example, a variable held in a cache in one processing set can be relegated to main memory in another. Main memory update cycles can execute in different orders. Memory writes on one processing set can be merged into a single cycle, while they can have multiple cycles on another. Even though I/O cycles in an asynchronous lockstep system can be easily compared, speed optimisations may make comparison of changes to the real state of the processing sets less easy. It is possible to build proper fault tolerant machines which take no notice of the real state. However, to diagnose faults quickly, both hardware and mutex software, it is desirable to detect divergence in real state quickly. This can be done by adding signature features to the processors, including a signature generator 150 and logic analyser 152, as represented in
Changes to the real state are made by the processors. If the real state is considered to include the register values inside the processor, every instruction which writes to a register updates the real state. A mechanism can be provided for comparing in detail the operation of synchronous systems through a limited bandwidth channel. The same signature mechanism can be used to compare all the processor register write data and instructions in an asynchronous deterministic system.
The processors have extra hardware added to them to create signatures of their internal operation. The signature is affected in some complex way by the data written by the processor, the register written to, and the order of the instructions. The signature is updated as each instruction is retired, in the effective order intended by the programmer, no matter what the order of execution by the processor is. It is possible to do this in a determined way even if the processor is fully asynchronous. From time to time, the monitor unit compares the signatures between processors on different compared processing sets. A convenient way to do this is to have the processors write their current signature from their respective signature generators 150 to the monitor unit just before they do their predictable interrupt-update cycles, described above. If the monitor unit detects equivalent processors have different signatures, it can cause corrective action to be taken.
There are different levels of comparison possible for signature generation.
Level one comparison can build signatures just from the write cycles to main memory, for example the SPARC ‘st’ operation. The address and data of each write cycle can update the processor signature. This will detect changes in the real state apart from register contents. A divergent value could lurk for a long time inside the processor without becoming visible. When it did become visible, it might be hard to find the reason for divergence. A logic analyser would need arbitrarily deep storage to find this. It should be noted that cycle merging (i.e. the tendency of load/store units to merge two adjacent small store operations into one large store operation) should be disabled.
Level two comparison builds signatures from all the main memory writes and also all the register writes too. This requires more hardware but guarantees that divergence is detected quickly, within a finite analyser storage requirement.
Level three comparison builds signatures from memory writes, register writes and memory reads. It is possible in a faulty system for all the writes from each processor to produce the same signature yet for the real state to be different, because writes from one processor overwrite those from another, and processor ordering differs between processing sets. While this, when eventually observed by changing write data signatures, can be detected by methods one and two, a neater detection method can use the data read as the real state as well. Register read data cannot be divergent in this way because registers are only writable by the local processor.
In combination with signature comparison, a small logic analyser built into the processors can provide excellent debug capability for mutex programming faults. The storage requirement for the logic analyser 152 is only enough to stretch from one signature comparison to the next. An analyser built into the processor can have a complete view of the instructions being executed, the data read from main memory, the data written to registers and the data written to main memory. Communication at runtime between the analysers in different processing sets and processors is not needed.
On a signature difference, the logic analysers in all the processors can be triggered. An interrupt can cause the processing sets to dump their (divergent) states to disk. The logic analyser data from each processor can also be dumped. The system can mail off the dump data for human analysis. The processing set can continue running, if possible.
There has, therefore, been described a multiprocessor computer system employing asynchronous processing sets which is suitable for forming a fault tolerant multiprocessor computer system. An embodiment of the invention is applicable to any system where one or more of a plurality of processing sets or processors is or are operating asynchronously of one or more of the other of the processing sets or processors.
Various embodiments of the invention can provide particular and preferred features, including one or more of the following:
a lockstep system using non-synchronized processing sets;
deterministic operation of asynchronous processors;
deterministic interrupt delivery in an unsynchronized system;
asynchronous comparison and synchronization by means of a monitor unit;
mutex ordering for asynchronous determinism;
a monitor unit for mutex ordering;
asynchronous lockstep for mutex fault discovery;
DMA mechanism with asynchronous determinism.
With an embodiment of the invention, lockstep fault tolerant systems can be built with different mask versions of the processors. One can also build lockstep fault tolerant systems with much more ordinary hardware that for conventional synchronized systems as there is no need for critical phase lock control of clocks. Lockstep fault tolerance can be effected with much reduced hardware redesign than is the case with synchronous approaches. Although asynchronous processors may use twice the transistors for the same design, they may run at one tenth the power consumption of synchronous systems. As the available transistor count increases for processor designers, asynchronous design may become commonplace for processors and an embodiment of the invention will enable the generation of lockstep systems using such processors. Careful design of the monitor unit allows I/O data access exceptions that are not totally precise, just restartable. This gives design freedom in the processor for bus operations.
There has been described a monitor for a multiprocessor system including a plurality of processing sets. At least one processing set is operable asynchronously of another processing set. The monitor is connectable to receive I/O operations output from the processing sets and to synchronise operation of the processing sets by signalling the processing sets on receipt of progress indications indicative of a plurality of the processing sets being at an equivalent stage of processing.
It will be appreciated that although particular embodiments of the invention have been described, many modifications/additions and/or substitutions may be made within the spirit and scope of the present invention as defined in the appended claims.
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|U.S. Classification||717/127, 709/209, 714/E11.069, 717/129, 714/E11.179, 714/11, 714/4.1|
|International Classification||G06F11/18, G06F11/22, G06F11/30, G06F9/44, G06F13/00, G06F11/16, G06F11/00, G06F15/177, G06F11/07, G06F9/46|
|Cooperative Classification||G06F9/52, G06F11/22, G06F11/1679, G06F11/1691, G06F9/526, G06F11/165, G06F11/004, G06F11/1683, G06F11/0745, G06F11/1641, G06F11/1654, G06F2201/88, G06F11/0724, G06F11/184, G06F11/0793, G06F11/30, G06F11/187, G06F11/2268|
|European Classification||G06F9/52, G06F11/07P1K, G06F9/52E, G06F11/18N2, G06F11/16T8, G06F11/16T4, G06F11/16C6, G06F11/00H, G06F11/07P10, G06F11/16C12|
|May 27, 2010||FPAY||Fee payment|
Year of fee payment: 4
|May 28, 2014||FPAY||Fee payment|
Year of fee payment: 8